Water Pentamer: Characterization of the Torsional-Puckering Manifold

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J. Phys. Chem. A 2005, 109, 6483-6497

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Water Pentamer: Characterization of the Torsional-Puckering Manifold by Terahertz VRT Spectroscopy Heather A. Harker,† Mark R. Viant,‡ Frank N. Keutsch,§ Ernest A. Michael,| Ryan P. McLaughlin,⊥ and Richard J. Saykally* Department of Chemistry, UniVersity of California, Berkeley, California 94720 ReceiVed: March 23, 2005; In Final Form: April 29, 2005

We present the measurement and analysis of five new (D2O)5 bands via vibration-rotation-tunneling (VRT) spectroscopy as well as a preliminary description of a second (H2O)5 band. The vibrationally averaged rotational constants of all five fitted bands agree well with those from the two previously observed (D2O)5 bands and confirm that the pentamer averages to a symmetric, quasi-planar structure on the time scale of our experiment. While the spectrum of the first two bands, located at 50.7 cm-1 (1.52 THz) and 27.3 cm-1 (0.82 THz) are indicative of unperturbed oblate rotors, the three remaining (D2O)5 bands centered at 47.7 cm-1 (1.43 THz), 45.4 cm-1 (1.36 THz), and 45.0 cm-1 (1.35 THz) are severely perturbed by first-order Coriolis coupling. This represents the first observation of this perturbation in the perdeuterated water pentamer, as well as the first observation of transitions between degenerate states of the torsional-puckering manifold. Unlike transitions from the (H2O)5 band observed by Brown et al. at 89.0 cm-1 and the 103.8 cm-1 band that we report here, none of the individual rovibrational transitions of any of the five (D2O)5 bands demonstrate spectral splittings due to bifurcation tunneling. We conclude, through careful analysis of these water pentamer bands, that at least three torsional-puckering manifolds have been probed and that the lowest-energy manifold is highly compacted. A plausible water pentamer torsional-puckering correlation diagram is proposed, though additional experimental data are required to unambiguously establish the energies of the torsional-puckering levels.

I. Introduction Because it presents an alternative to the traditional tetrahedral structure as a means of achieving an ideal hydrogen bonding geometry, the water pentamer plays a special role in the hydrogen-bond network topologies of liquid water, larger water clusters, clathrate hydrates, and hydration shells of proteins and DNA.1,2 Ohmine showed that hydrogen-bond-network rearrangements (HBNR) in liquid water interconvert small aggregates such as the pentamer, hexamer, and so forth on a time scale much longer than that of the intermolecular vibrational modes of a typical water cluster and that identifiable five- and six-membered rings dominate the topology in the HBN.3 Collective motions of the HBN underlie the many unusual properties of liquid water, for example, the high melting and boiling points, the large heat capacity, and the density maximum at 4 °C. Wales et al. have shown stacked pentameric rings to be prevalent in the global minima energy structures of larger water clusters,4 while Ma et al. demonstrated the presence of fused rings of puckered, cyclic water pentamers in crystalline hydrates,5 with the pentamer structure being very similar to that determined by vibration-rotation-tunneling (VRT) spectroscopy, and Burnham et al. have found the global minimum * To whom correspondence should be addressed: [email protected]. † [email protected]. ‡ Present address: School of Biosciences, The University of Birmingham, Birmingham, B15 2TT, U.K.; [email protected]. § Present address: Department of Chemistry and Chemical Biology, Harvard University, Cambridge, MA 01238.; [email protected]. | Present address: I. Physik Institut, Universita ¨ t zu Ko¨ln, Germany.; [email protected]. ⊥ Present address: Department of Chemistry, University of Washington, Seattle, WA 98195.; [email protected].

Figure 1. Torsional-puckering dynamics of the water pentamer. Flipping motion of a free hydrogen atom accompanied by the oxygen framework pucker pseudorotation; vibrational averaging of the C1 equilibrium structure yields an effective C5h structure.

pentamer ring structure to form readily even at liquid helium temperatures.6 Although infrared cavity ringdown spectroscopy of the gas-phase water pentamer reveals intramolecular absorption features of the gas-phase water pentamer that match the spectral features of the pentamer rings trapped inside helium droplets, as well as those of liquid water and amorphous ice,6-8 the IR absorptions appear as single narrow peaks presumably due to the floppy aspect of the puckered water pentamer oxygen framework that allows for enhanced coupling between the intraand intermolecular vibrational modes. In contrast, VRT spectroscopy directly probes the intermolecular vibrations and reveals the detailed fine structure that arises from quantum tunneling between degenerate minima. The ab initio calculated equilibrium structure of the water pentamer is an asymmetric (C1), chiral homodromic ring, wherein each water molecule acts as both a single hydrogenbond donor and acceptor. The free hydrogen atom positions alternate above and below the oxygen ring framework (Figure 1).9 While the pentamer structure may appear to be a direct extension of that of the trimer, theory indicates that the pentamer

10.1021/jp051504s CCC: $30.25 © 2005 American Chemical Society Published on Web 06/17/2005

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Figure 2. Bifurcation tunneling splittings in the water trimer-d6. Exchange of a free and a bound hydrogen atom on an individual monomer is accompanied by the flipping of the free hydrogen atoms on the neighboring water molecules. This is the lowest-energy hydrogen-bond breaking motion, observed in the dimer, hexamer, and all cyclic water clusters except the water tetramer, and results in each rovibrational transition of the water trimer splitting into a quartet, with relative intensities determined by nuclear spin statistics.20,21

Harker et al.

Figure 3. Bifurcation tunneling splittings in the 89.0 cm-1 H2O water pentamer band. The exchange of a free and a bound hydrogen atom is shown accompanied by the flipping of the free hydrogen atom on the neighboring water molecule whose oxygen atom is the hydrogen-bond acceptor of the bifurcated transition state. In contrast to the water trimer, flipping of free hydrogen atoms, as well as bifurcation tunneling in the pentamer, requires a simultaneous pseudorotation of the oxygen framework pucker (Figure 1). Note: Only four tunneling components were observed because of nuclear spin statistics and degeneracies.

TABLE 1: Observed Bifurcation Tunneling Splittings and Predicted Barriers of Torsional Bands (H2O)3

oxygen framework is puckered by 13° or more,10 whereas the trimer framework is obviously planar. Terahertz VRT experiments on the water pentamer have shown that vibrational averaging via the facile torsional flipping of free hydrogen atoms is accompanied by pseudorotation of the ring pucker, resulting in a planar, symmetric (C5h) effective structure (Figure 1).2,11,12 We note here that the water pentamer torsional-puckering energy manifold may elsewhere have been referred to simply as a torsional or pseudorotational manifold, but that the designation of “torsional-puckering” manifold better distinguishes this manifold from that of the water trimer. Liu et al. observed the first (D2O)5 VRT band in 1997 by Terahertz laser spectroscopy.13 Whereas previous high-resolution VRT experiments on the water dimer,14 trimer,15 and hexamer16 had shown that HBNR dynamics occurring within these water clusters were manifested as small tunneling splittings of each rovibrational transition (Figure 2), the parallel (∆K ) 0) band, measured by Liu et al. at 81.2 cm-1, as well as an additional parallel band measured shortly thereafter at 30.2 cm-1 by Cruzan et al.,11 were both devoid of observable bifurcation tunneling splittings. It was not until Brown et al. reported the first (H2O)5 band at 89.0 cm-1, wherein each rovibrational transition was split into four observable lines separated by 4.8 MHz, that the bifurcation tunneling splittings, predicted by theoretical efforts,17-19 were observed in the water pentamer (Figure 3).12 The observed bifurcation tunneling splittings in the (H2O)5 water pentamer were, however, 60 times smaller than those of the typical torsional (H2O)3 trimer (Table 1). This is not surprising given the greater hydrogen-bond strength in the water pentamer and the coupling of the free hydrogen flipping motion, as well as bifurcation tunneling to the ring pucker pseudorotation, which requires accompanying motion of the heavy oxygen atom framework (Figure 1). Given that the bifurcation splitting decreases by a factor of 8-300 going from the H6 to the D6 water trimer and that the analogous splitting in the H10 water pentamer is at best 5 times the spectral resolution of the terahertz spectrometer, it seems improbable that bifurcation tunneling splittings will be observed for the perdeuterated water pentamer. While this generates a simpler spectrum, it obviates both a powerful cluster identification tool and valuable dynamical information.

barrier (cm-1) splitting (MHz) a

b

(D2O)3 819a

40-300c c

0 transition is split into two, one on either side

of the solitary K ) 0 transition. Furthermore, while the magnitude of the splitting increases with K, for a given K, the splitting remains constant regardless of J. For example, the K ) 1 R-branch transitions are split into two, separated by 183 MHz, while all K) 6 R-branch transition pairs, regardless of J, are split by a greater, yet constant amount (viz., 1096 GHz). The magnitude of the observed splitting in the P- and R-branches of these three bands is therefore clearly independent of J and increases in a regular manner with K. Moreover, the splitting is linearly dependent on K for all three of these Coriolis perturbed bands. The linear dependence of the splitting on K is consistent with the presence of first-order Coriolis coupling. Second-order Coriolis effects observed in the 28 cm-1 (D2O)3 band by Viant et al.29 are manifested as relatively large (∼17 MHz) errors in the fit residuals for high J transitions in particular K states (K ) 2 in the case of this particular trimer band) relative to the other K states. Because of the similarities in structure and dynamics between the trimer and the pentamer, it is reasonable to expect second-order Coriolis coupling to occur in the pentamer. However, inspection of the residuals in Tables IXS, XS, and XIS (Supporting Information) indicate that, in accord with Brown’s (H2O)5 band, only first-order Coriolis coupling is present in the pentamer. Therefore, while it is likely

Torsional-Puckering Manifold of Water Pentamer

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Figure 12. 47.7 cm-1 (1432.2700 GHz) band of (D2O)5. The bottom graph shows a stick spectrum of the 208 observed transitions for this parallel band, the middle graph an expanded view of the repelling Q-branch region, and the top graph an expanded view of the actual scans of Q(7)-Q(9) of the K ) 7 stack.

TABLE 5: Spectroscopic Parameters (MHz) by Band as Determined via Least-Squares Analysisa B′′ DJ′′ DJ′′,K′′ νo B′ DJ′ DJ′,K′ ∆C σrms a

27.3 cm-1

50.7 cm-1

30.2 cm-1 b

81.2 cm-1 c

1750.87 (4) 0.0031 (1) -0.0077 (7) 818 231.2 (2) 1751.57 (4) 0.0031 (1) -0.0077 (7) 4.428 (3) 0.63

1751.014 (8) 0.003 64 (2) -0.006 48 (6) 1 521 344.3 (1) 1751.738 (8) 0.003 59 (3) -0.006 41 (6) 5.267 (2) 0.86

1750.964 (2) 0.003 24 (2) -0.006 91 (6) 905 368.415 (9) 1751.116 (2) )DJ′′ )DJ′′,K′′ 2.421 56 (9) 0.56

1750.815 (8) 0.001 59 (5) -0.0048 (2) 2 434 074.36 (6) 1751.163 (8) 0.001 63 (5) -0.0048 (2) 5.267 (2) 3.4

1σ uncertainty of last significant digit in parentheses. b ref 11. c ref

13.

that a second-order Coriolis effect does occur in the water pentamer, there is no definitive signature of its presence in any of the four Coriolis perturbed pentamer bands, and thus, this effect was not included in the final fits of the 45.0, 45.4, and 47.7 cm-1 bands. The oblate symmetric top energy expression given in eq 1 was modified according to Teller40 to include the first-order Coriolis coupling term (2ζC, where ζ is the coupling constant

and C is the Bz rotational constant for an oblate rotor. The minus sign applies if the vibrational angular momentum has the same direction as the rotational angular momentum, whereas the plus sign applies if they are in opposing directions

EνJ,K ) ν + BJ(J + 1) + (C - B)K2 - DJJ2(J + 1)2 DJ,KJ(J + 1)K2 - DKK4 ( 2ζCK (2) The resulting rotational parameters are listed in Table 6. The rms values of the fit residuals are 1.49, 1.80, and 1.61 MHz for the 45.0, 45.4, and 47.7 cm-1 bands, respectively, well within the experimental error of ∼3 MHz yet slightly greater than the spectral resolution of 1 MHz. Correlation matrices for these three bands can be found in Table XIIIS (Supporting Information). While it is difficult to compare the rms values for the unperturbed bands among one another, given that they span a large frequency region and therefore have very different spectral resolutions and intensities due to the relative strength of the FIR lasers used, it is quite possible to compare the 45.0 and 45.4 cm-1 bands, since they overlap in frequency. The 45.0 cm-1 band is the second weakest and most highly perturbed of

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Harker et al. provide rotational constants and other spectroscopic parameters, but we can make a few general remarks. First, this band is unperturbed and has a band origin of roughly 103.8 cm-1. Second, each rovibrational transition exhibits bifurcation tunneling splittings analogous to those found in the 89 cm-1 band reported by Brown et al.12 Again, only four of the tunneling components were observed due to nuclear spin statistics and degeneracies. However, the splitting was twice as large (viz., ∼11 MHz compared to 4.8 MHz for the 89 cm-1 band). In total, 409 transitions, including all bifurcation tunneling components, were attributed to this H2O pentamer band (Figure 14). We note that measurement of a band exhibiting bifurcation tunneling splittings that involves Coriolis perturbed states is required to determine the dynamics that give rise to the observed bifurcation splitting patterns. Indeed, all three splitting patterns determined by Wales et al. predict four equally spaced transitions for non-Coriolis perturbed states but uniquely split transitions for Coriolis perturbed states. Each of the three splitting patterns is associated with bifurcation tunneling accompanied by a precise number of free hydrogen flips.17-19

Figure 13. First-order Coriolis effects on R(6) transitions. The top graph shows a stick spectrum of the seven R(6) transitions of the unperturbed, oblate symmetric rotor band at 50.7 cm-1 (the K ) 4 transition is tagged because it was not observed experimentally). The bottom graph shows a stick spectrum of the thirteen R(6) transitions of the Coriolis perturbed band at 45.4 cm-1.

TABLE 6: Spectroscopic Parameters (MHz)a B′′ DJ′′ DJ′′,K′′ νo B′ DJ′ DJ′,K′ ∆DK ∆C ∆ζ σrms a

45.0 cm-1

45.4 cm-1

47.7 cm-1

1751.976 (77) 0.0019 (10) -0.0116 (29) 1 350 662.5 (4) 1752.787 (76) 0.0017 (10) -0.0089 (29) -0.0038 (3) 3.99 (2) 20.007 (80) 1.49

1750.859 (42) 0.0029 (5) -0.0071 (12) 1 362 641.2 (2) 1752.055 (42) 0.0026 (5) -0.0069 (12) 0.000 46 (3) 4.141 (3) 11.072 (9) 1.80

1751.335 (25) 0.0031 (1) 0.0043 (4) 1 432 270.0 (3) 1752.277 (26) 0.0032 (2) 0.0073 (4) -0.000 50 (9) 5.159 (7) 7.307 (9) 1.61

1σ uncertainty of last significant digit in parentheses.

all the measured (D2O)5 bands with only 112 fit transitions, most of which arise from J e 15. The 45.4 cm-1 band, on the other hand, is the strongest of the perturbed bands, with 398 fit transitions and consistently high J values peaking at J ) 25. The rms values of these two bands, 1.49 and 1.80 respectively, are not only similar, but are also not much greater than those of the unperturbed bands, particularly at comparable frequencies. Arguably, the 50.7 cm-1 band with its 0.86 rms was scanned on a different FIR laser line, but it was of comparable strength. We conclude that Coriolis effects have been properly accounted for with first-order terms, since rms values remain fairly constant regardless of the presence of Coriolis perturbation and the addition of high J transitions. It should be noted that DK and ζ, like the C rotational constant, depend only on K and therefore cannot be determined independently from the fit of a parallel band. C. 103.8 cm-1 (H2O)5 Band. One additional H2O pentamer band has been identified. Unfortunately, the exceedingly compact nature of this band, compounded by overlapping and unresolved bifurcation tunneling components, prevents unambiguous fitting of the observed transitions. Therefore, we cannot

V. Discussion Although it is difficult to rigorously interpret and compare the fitted parameters of the seven (D2O)5 bands, a few general remarks can be made. First, only small changes,